KR20220167040A - Apparatus for determining whether or not an arc abnormality to prevent fire of photovoltaic system - Google Patents

Abstract

The present invention relates to an apparatus for determining the presence of anomaly in an arc to prevent a fire in a photovoltaic system, wherein when an arc detection analog circuit unit (56) matches and amplifies an electrical current and an arc detected by an electrical current/arc sensor (52) with an analog signal, an AD conversion unit (57a) converts the analog signal into a digital signal and an FFT (57b) interprets the digital signal of the AD conversion unit (57a) in a frequency area to identify signal power distribution, further allow an unnecessary band removal unit (57c) to remove a noise band from the signal power distribution of the FFT (57b), allow an effective band power calculation unit (57d) to calculate power of an effective band in the signal power distribution, direct an arc band power calculation unit (57e) to calculate power of an arc band when the electrical current/arc sensor (52) detects an arc, and then allow a power comparison/warning issuing unit (57f) to compare the power of the effective band of the effective band power calculation unit (57d) with the power of the arc band of the arc band power calculation unit (57e) and issue a warning signal when a different therebetween is greater than or equal to a critical point, thereby enabling presence of anomaly in an arc on a transmission line to be accurately determined.

Description

Arc abnormality detection device for fire prevention of photovoltaic power generation system

The present invention relates to an arc abnormality detection device for fire prevention in a photovoltaic power generation system, and more particularly, when an arc detection analog circuit unit matches and amplifies a current and an arc detected from a current/arc sensor into an analog signal, AD conversion is performed. The analog signal is converted into a digital signal in the unit, and the digital signal of the AD conversion unit is analyzed in the frequency domain through FFT to determine the signal power distribution. After calculating the power of the effective band from the signal power distribution through the band power calculator and calculating the power of the arc band when the current/arc sensor detects an arc through the arc band power calculator, the power comparison/warning generating unit calculates the active band power Comparing the power of the effective band of the calculator and the power of the arc band of the arc band power calculator and generating a warning signal when the difference between them is greater than a threshold value, so that it can accurately determine whether or not there is an arc abnormality on the transmission line. It relates to an arc abnormality detection device for fire prevention of a power generation system.

In recent years, as public interest in realizing a safe society has increased, public interest in electrical fires has also increased. Anxiety is amplifying. In addition, the annual average number of domestic fires in the last 10 years is 42,000, and electrical fires account for up to 20% of 9,000 cases.

The biggest cause of electrical fires can be said to be fires caused by arcs, and technologies for detecting arcs that cause electrical fires are currently being invented in various forms.

8 is a view for explaining a photovoltaic cell string and a photovoltaic connection board according to an embodiment of the prior art document (Korean Patent Publication No. 2020-0127406), and FIG. 9 is an arc generation according to an embodiment of the prior art document 10 is a block diagram for explaining a device for detecting and removing an arc of a photovoltaic junction panel according to an embodiment of a prior art document.

A device for detecting and removing an arc of a solar junction panel for fire prevention according to prior art documents is a sensor for detecting an arc generated from wiring of a plurality of solar cell strings 10 as shown in FIGS. 8 to 10 Unit 110, a serial arc processing unit 120 connected in series to the wiring of the plurality of photovoltaic cell strings 10, and a parallel arc processing unit connected in parallel to the wiring of the plurality of photovoltaic cell strings 10 ( 130) and when an arc is detected through the sensor unit 110, the serial arc processing unit 120 controls to block the wires connected in series, and after blocking the wires connected in series, the sensor unit 110 still When an arc is detected, a control unit 150 controls the parallel arc processor 130 to short circuit both ends of the wire where the arc is detected.

11 is a flowchart for explaining a method for detecting and removing an arc of a photovoltaic junction panel according to an embodiment of a prior art document.

A method for detecting and removing an arc of a solar junction panel for fire prevention according to prior art literature is monitoring whether an arc occurs in a wiring connected to a plurality of photovoltaic cell strings 10 as shown in FIGS. 8 to 11 Step (S110), blocking the wiring connected in series to the plurality of photovoltaic cell strings 10 when arcs are detected as a result of monitoring (S130), cutting off the wiring connected in series, and still detecting arcs (S150) and, if the arc is still detected as a result of the check (S150), short-circuiting both ends of wires connected in parallel to the plurality of photovoltaic cell strings (10) (S160).

The applicant of the present application has further developed a device for detecting and removing an arc of a solar junction panel for fire prevention according to prior art documents and a method therefor to further develop an arc abnormality detection device for fire prevention of a photovoltaic power generation system according to the present invention would like to propose

Republic of Korea Patent Publication No. 2020-0127406

An object of the present invention is to match and amplify the current and arc detected by the current/arc sensor into an analog signal in the arc detection analog circuit unit, convert the analog signal into a digital signal in the AD conversion unit, and convert the digital signal of the AD conversion unit through FFT. Analysis in the frequency domain to understand the signal power distribution, and furthermore, removing the noise band from the signal power distribution of the FFT through the unnecessary band removal unit, calculating the power of the effective band from the signal power distribution through the effective band power calculation unit, and calculating the arc band power After allowing the current/arc sensor to calculate the power of the arc band when the arc is detected, the power comparison/warning generating unit compares the power of the effective band of the active band power calculation unit and the power of the arc band of the arc band power calculation unit to mutually It is to provide an arc abnormality detection device for fire prevention of a photovoltaic power generation system capable of generating a warning signal when the difference in is greater than a threshold value to accurately realize the presence or absence of an arc abnormality on a transmission line.

An arc abnormality detection device for fire prevention of a photovoltaic power generation system according to the present invention for achieving the above object is,

An arc detection analog circuit unit that matches and amplifies the current and arc sensed from the current/arc sensor connected to the PV array that generates 300-1500V direct current through an array of photovoltaic (PV) modules into an analog signal,

an AD conversion unit for converting the analog signal matched and amplified by the arc detection analog circuit unit into a digital signal;

FFT (Fast Fourier Transform) that interprets the digital signal of the AD conversion unit in the frequency domain to determine the signal power distribution;

an unnecessary band removal unit for removing a noise band from the signal power distribution of the FFT;

an effective band power calculation unit for calculating power in an effective band from the signal power distribution from which the noise band is removed by the unnecessary band removal unit;

An arc band power calculator for calculating arc band power when the arc is sensed by the current/arc sensor;

A basic technical configuration includes a power comparison/warning generating unit that compares the effective band power of the active band power calculator and the arc band power of the arc band power calculator and generates a warning signal when the difference between them is greater than or equal to a threshold value. to be characterized

In the present invention, when the arc detection analog circuit unit matches and amplifies the current and arc detected by the current/arc sensor into an analog signal, the AD conversion unit converts the analog signal into a digital signal, and converts the digital signal of the AD conversion unit into a frequency domain through FFT. Analyzed in and figure out the signal power distribution, and further remove the noise band from the signal power distribution of FFT through the unnecessary band removal unit, calculate the power of the effective band from the signal power distribution through the effective band power calculation unit, and through the arc band power calculation unit After the current/arc sensor calculates the power of the arc band when detecting an arc, the power comparison/warning generating unit compares the power of the effective band of the active band power calculation unit and the power of the arc band of the arc band power calculation unit to differentiate between each other. When is greater than the threshold value, a warning signal is generated to accurately determine the presence or absence of an arc abnormality on the transmission line.

The present invention further includes an effective band selector for selecting an unnecessary band and an arc band by monitoring the signal power distribution of the FFT, so that misreading due to unnecessary bands can be reduced as much as possible.

The present invention has an effect of ensuring accuracy of reading about arc generation by matching and amplifying current and arc by a current/arc sensor.

1 is a block diagram showing a photovoltaic power generation system according to the present invention;
2 is a block diagram showing a smart junction box applied to a photovoltaic system according to the present invention.
3 is a block diagram showing an arc abnormality detection device for fire prevention of a photovoltaic power generation system according to the present invention;
4A and 4B are graphs illustrating frequency analysis of noise on a photovoltaic transmission line for explaining a photovoltaic power generation system according to the present invention.
5 is a conceptual diagram illustrating a current/arc sensor applied to an arc abnormality detection device for fire prevention of a photovoltaic power generation system according to the present invention.
6 is a flowchart illustrating an arc detection initialization process for explaining a method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention.
7A is a flowchart illustrating a method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to a first embodiment of the present invention.
7B is a flowchart illustrating a method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to a second embodiment of the present invention.
8 is a view for explaining a photovoltaic cell string and a photovoltaic connection board according to an embodiment of the prior art document.
9 is a view for explaining the cause of arc generation according to an embodiment of the prior art document.
10 is a block diagram for explaining a device for arc detection and removal of a solar connection board according to an embodiment of the prior art document.
11 is a flowchart illustrating a method for detecting and removing an arc of a solar panel according to an embodiment of a prior art document.

A preferred embodiment of a device for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention will be described with reference to the drawings, and a plurality of examples may exist. Through these embodiments, the present invention better understand its purpose, features and benefits.

1 is a block diagram showing a photovoltaic power generation system according to the present invention.

As shown in FIG. 1, the photovoltaic power generation system according to the present invention includes a PV array 30 generating DC electricity of 300 to 1500V through an array of photovoltaic (PV) modules 31, and the PV array A smart junction box 50 having a DC monitoring unit 51 that receives the surrounding environmental conditions from the environment sensor 40 while monitoring and protecting the DC electricity generated from (30), and the DC electricity of the smart junction box 50 The inverter 60 that converts AC electricity into AC electricity, the power distribution board 70 that supplies AC electricity from the inverter 60 to the power grid, and the monitoring status and environmental status through the smart junction box 50 are monitored through a data server through a wired/wireless communication network. It includes a system monitoring unit 80 that transmits data to (90) and a data server 90 that analyzes the monitoring status of the smart junction box 50 via the system monitoring unit 80 and monitors it in real time.

When DC electricity of 300 ~ 1500V is generated through the array of solar modules 31 in the PV array 30, the DC electricity of the PV array 30 is monitored and protected through the DC monitoring unit 51, and the smart connection is made ( 50) transmits power to the inverter 60, converts the DC electricity of the smart junction box 50 into AC electricity in the inverter 60, and supplies the AC electricity of the inverter 60 to the power grid through the distribution panel 70 do.

At this time, the system monitoring unit 80 transmits the monitoring status and environmental status through the smart junction box 50 to the data server 90 through a wired or wireless communication network, and the data server 90 via the system monitoring unit 80. The monitoring state of one smart junction box 50 is analyzed to enable real-time monitoring.

2 is a block diagram showing a smart junction box 50 applied to a photovoltaic system according to the present invention.

As shown in FIGS. 1 and 2 , the smart junction box 50 applied to the photovoltaic power generation system according to the present invention detects current and arc from the DC electric line of the PV array 30 and sends it to the DC monitoring unit 51. It monitors and protects the current/arc sensor 52 that transmits and the current and arc detected by the current/arc sensor 52, and at the same time receives the surrounding environment state from the environment sensor 40 to the system monitoring unit 80. The DC monitoring unit 51 that transmits, the fuse 53 that is cut off when overcurrent flows in the direct current electric line of the PV array 30, and the DC monitoring unit 51 cuts off the circuit when the leakage state is confirmed. It includes a circuit breaker 54 and a surge protector device (SPD) 55 that protects the circuit when lightning and overvoltage are detected.

When the current/arc sensor 52 detects the current and arc from the DC electric line of the PV array 30 and transmits them to the DC monitoring unit 51, the DC monitoring unit 51 detects them from the current/arc sensor 52. At the same time as monitoring and protecting the current and arc, the environment sensor 40 receives the surrounding environment state and transmits it to the system monitoring unit 80, and at this time, when overcurrent flows in the DC electric line of the PV array 30, the fuse ( 53) is blocked, the circuit breaker 54 blocks the circuit when the leakage state is confirmed by the DC monitoring unit 51, and the SPD 55 protects the circuit when lightning and overvoltage are detected.

At this time, the arc abnormality detection device for fire prevention of the photovoltaic power generation system according to the present invention compares the arc detected from the current/arc sensor 52 with a threshold value to determine whether or not it can cause a fire and display the result.

3 is a block diagram showing an arc abnormality detection device for fire prevention of a photovoltaic power generation system according to the present invention, and FIGS. 4a and 4b are solar power transmission line noise for explaining the photovoltaic power generation system according to the present invention. It is a graph illustrating frequency analysis of , and FIG. 5 is a conceptual diagram for explaining a current/arc sensor 52 applied to an arc abnormality detection device for fire prevention of a photovoltaic power generation system according to the present invention.

As shown in FIGS. 1 to 5, the device for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention generates a PV array of 300 to 1500V DC electricity through an array of photovoltaic modules 31. Current/arc sensor connected to (30) [52: Rogowski Coil; 52a) - Toroid type non-contact type current sensor. An arc detection analog circuit unit 56 that matches and amplifies the detected current and arc into an analog signal, and the analog signal matched and amplified by the arc detection analog circuit unit 56 into a digital signal. From the AD converter 57a that converts, the FFT (Fast Fourier Transform; 57b) that analyzes the digital signal of the AD converter 57a in the frequency domain and grasps the signal power distribution, and the signal power distribution of the FFT 57b An unnecessary band removal unit 57c that removes noise bands, an effective band power calculator 57d that calculates power in an effective band from the signal power distribution from which noise bands have been removed by the unnecessary band removal unit 57c, and When the arc sensor 52 detects an arc, the arc band power calculator 57e calculates the power of the arc band, and the active band power of the effective band power calculator 57d and the arc of the arc band power calculator 57e A power comparison/warning generating unit 57f that compares the powers of the bands and generates a warning signal when the difference between them is greater than a threshold value is included.

When the arc detection analog circuit unit 56 matches and amplifies the current and arc detected by the current/arc sensor 52 into an analog signal, the AD conversion unit 57a converts the analog signal into a digital signal, and then the FFT 57b analyzes the digital signal of the AD conversion unit 57a in the frequency domain to determine the signal power distribution, and further removes the noise band from the signal power distribution of the FFT 57b through the unnecessary band removal unit 57c to obtain the effective band power After calculating the power of the effective band from the signal power distribution through the calculator 57d and calculating the power of the arc band when the current/arc sensor 52 detects an arc through the arc band power calculator 57e, the power The comparison/warning generator 57f compares the active band power of the active band power calculator 57d and the arc band power of the arc band power calculator 57e, and generates a warning signal when the difference between them is greater than a threshold value. By enabling this to occur, it is possible to accurately determine the presence or absence of an arc abnormality on the transmission line.

At this time, the apparatus for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention further includes an effective band selector 57g for selecting an unnecessary band and an arc band by monitoring the signal power distribution of the FFT 57b. Thus, misreading due to unnecessary bands can be reduced as much as possible.

Meanwhile, the arc detection analog circuit unit 56 includes a matching circuit unit 56a that converts the current and arc detected by the current/arc sensor 52 into voltage, and an AD conversion unit 57a by amplifying the voltage of the matching circuit unit 56a. ) and a signal amplifying unit 56b that transmits to the current/arc sensor 52, matching and amplifying the current and arc sensed by the current/arc sensor 52 to ensure accuracy of reading about arc generation.

6 is a flowchart illustrating an arc detection initialization process for explaining a method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention.

A method for determining whether or not there is an arc abnormality for fire prevention in a photovoltaic power generation system according to the present invention determines parameters required for operation by performing an arc detection initialization process as shown in FIGS. 1 to 6 .

That is, the method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention is the quantization of the AD conversion unit 57a for converting the analog signal matched and amplified in the arc detection analog circuit unit 56 into a digital signal. FFT (57b) processing of the data to form a spectrum (X _{FFT (57b)} ) analysis in the frequency domain and confirmation [the spectrum can be output to a display device for operator analysis or displayed as a graphic or table on an LCD] Step ( S10) and active band power (Pt) while selecting unnecessary band (EN _DEL ), arc band (EN _ARC ) and normal threshold (N _TH ) from the frequency domain spectrum (X _{FFT (57b)} ) processed by FFT (57b) ) and the step (S20) of calculating the arc band power (Pa), and when the value obtained by subtracting the active band power (Pt) from the arc band power (Pa) is smaller than the normal threshold value (N _TH ) [|Pa-Pt| < In case of N _TH ] Assume a normal state, but if it does not match, the step of repeatedly determining parameters suitable for the photovoltaic system environment (S30), and subtracting the active band power (Pt) from the arc band power (Pa) If one value is greater than the normal threshold (N _TH ) [|Pa-Pt| > N _TH ] Band to be excluded from calculation due to presence of noise power (EN _DEL ), band with strong signal when arc occurs (EN _ARC ), active band power (Pt) and arc band power (Pa) Parameters required for operation are determined by performing an arc detection initialization process including a step ( S40 ) of determining and storing a normal threshold value (N _TH ) at which it can be determined that the power is the same.

FFT (57b) processes the quantized data of the AD conversion unit (57a), which converts the analog signal matched and amplified by the arc detection analog circuit unit (56) into a digital signal, and analyzes the spectrum (X _{FFT (57b)} ) in the frequency domain. After _forming and _confirming , the effective _band power ( _Pt ) and arc band power (Pa), and if the value obtained by subtracting the active band power (Pt) from the arc band power (Pa) is smaller than the normal threshold (N _TH ), [|Pa-Pt| < In case of N _TH ] Assume a normal state, but if it does not match, it is repeated to determine parameters suitable for the solar power generation system environment to enable accurate reading of whether or not arc occurs, and furthermore, effective band from arc band power (Pa) If the value obtained by subtracting the power (Pt) is greater than the normal threshold (N _TH ) [|Pa-Pt| > N _TH ] Band to be excluded from calculation due to presence of noise power (EN _DEL ), band with strong signal when arc occurs (EN _ARC ), active band power (Pt) and arc band power (Pa) A normal threshold value (N _TH ) that can be determined to have the same power is determined and stored to ensure the accuracy of determining whether or not there is an arc abnormality.

At this time, a step ( S50 ) of processing data based on the parameter determined in the arc detection initialization process and generating an arc alarm based thereon is further included to further improve accuracy upon arc alarm.

Specifically, the method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to the present invention processes data based on parameters determined in an initialization process and generates an arc alarm based on this.

At this time, the arc threshold (A _TH ) is empirically determined based on the normal threshold. It can be determined by adding an offset or by calculating a ratio, and can be selected according to system conditions. Arc band power (Pa) and active band power (Pt) are calculated and compared based on parameters determined in the initialization process, and arc band power (Pa ) is greater than the arc threshold (A _TH or A _TH2 ) than the active band power (Pt) or the steady-state arc band power (Ps), it is judged as arc generation and accuracy is guaranteed.

7A is a flowchart illustrating a method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to a first embodiment of the present invention.

As a method for determining whether or not there is an arc abnormality for fire prevention in a photovoltaic power generation system according to the present invention, the step (S50) of processing data based on the parameters determined in the arc detection initialization process and generating an arc alarm based on this is further embodied. As shown in FIGS. 1 to 6 and 7A, data is processed based on parameters determined in the initialization process, and an arc alarm can be generated based on this.

Processing data based on the parameters determined in the arc detection initialization process according to the arc abnormality detection method for fire prevention of a photovoltaic power generation system according to the first embodiment of the present invention, and generating an arc alarm based on this step (S50 ) is a step (S51) of determining the arc threshold (A _TH ) while recalling the parameters (EN _DEL , EN _ARC , N _TH ) of the arc detection initialization process as shown in FIGS. A _TH ) is determined empirically based on the normal threshold. It can be determined by adding an offset or by calculating a ratio and can be selected by the operator according to system conditions] and parameters (EN _DEL , EN _ARC , N _TH ) If the calculating step (S52) and the arc band power (Pa) is greater than the sum of the active band power (Pt) and the arc threshold (A _TH ), it is determined that an arc has occurred and the arc band power (Pa) is the active band power (Pt) ) and the arc threshold (A _TH ), the step of repeating the comparison (S53), and the arc alarm if the arc band power (Pa) is greater than the sum of the active band power (Pt) and the arc threshold (A _TH ) and generating a step (S54).

The arc threshold value (A _TH ) is determined while recalling the parameters (EN _DEL , EN _ARC , N _TH ) of the arc detection initialization process, and based on this parameter (EN _DEL , EN _ARC , N _TH ), the arc bandwidth power (Pa) And after calculating the active band power (Pt), if the arc band power (Pa) is greater than the sum of the active band power (Pt) and the arc threshold value (A _TH ), it is judged as arc generation and the arc band power (Pa) is the effective band If it is smaller than the sum of the power (Pt) and the arc threshold (A _TH ), the comparison is repeated, and if the arc band power (Pa) is greater than the sum of the active band power (Pt) and the arc threshold (A _TH ), an arc alarm is generated. By doing so, it is possible to more accurately determine the presence or absence of an abnormality in the arc generated in the transmission line of the photovoltaic power generation system.

At this time, if the arc band power (Pa) is greater than the sum of the active band power (Pt) and the arc threshold value (A _TH ) after the step S53 is more than a predetermined number (M), an arc alarm is generated (S53+1) It further includes to minimize misreading of the arc.

7B is a flowchart illustrating a method for determining the presence or absence of an arc abnormality for fire prevention of a photovoltaic power generation system according to a second embodiment of the present invention.

Processing data based on parameters determined in the arc detection initialization process according to the arc abnormality detection method for fire prevention of a photovoltaic power generation system according to the second embodiment of the present invention, and generating an arc alarm based on this step (S60 ) is a step (S61) of determining the arc threshold (A _TH2 ) while recalling the parameters (EN _DEL , EN _ARC , Ps) of the arc detection initialization process as shown in FIGS. 1 to 6 and 7B [at this time, Ps denotes the arc band power (Pa) in the steady state calculated in the initialization process, and the arc threshold (A _TH2 ) is empirically determined based on the normal threshold. It can be determined by adding an offset or by calculating a ratio and can be selected by an operator according to system conditions] and calculating arc band power (Pa) based on parameters (EN _DEL , EN _ARC , Ps) (S62); If the arc band power (Pa) is greater than the sum of the steady state arc band power (Ps) and the arc threshold (A _TH2 ), it is determined that an arc has occurred, and the arc band power (Pa) is the normal state arc band power (Ps) and If it is less than the sum of the arc threshold (A _TH2 ), the step of repeating the comparison (S63), and arc alarm if the arc band power (Pa) is greater than the sum of the steady state arc band power (Ps) and the arc threshold (A _TH2 ) and generating a step (S64).

Arc threshold (A _TH2 ) is determined while recalling parameters (EN _DEL , EN _ARC , Ps) of the arc detection initialization process, and arc bandwidth power (Pa) is calculated based on these parameters (EN _DEL , EN _ARC , Ps) After that, if the arc band power (Pa) is greater than the sum of the steady state arc band power (Ps) and the arc threshold (A _TH2 ), it is judged as an arc occurrence, and the arc band power (Pa) is the normal state arc band power (Ps) and If it is smaller than the sum of the arc threshold value (A _TH2 ), the comparison is repeated, and if the arc band power (Pa) is greater than the sum of the normal state arc band power (Ps) and the arc threshold value (A _TH2 ), an arc alarm is generated to generate solar It is possible to more accurately determine whether or not there is an abnormality in the arc generated in the power transmission line of the photovoltaic system.

At this time, after the step S63, if the case where the arc band power (Pa) is greater than the sum of the normal state arc band power (Ps) and the arc threshold (A _TH2 ) is more than a predetermined number (M), an arc alarm is generated (S63+ 1) is further included to minimize arc misreading.

The present invention can be used in industrial fields related to power transmission lines of solar power generation systems.

30: PV array 31: solar module
40: environmental sensor 50: smart connection box
51: DC monitoring unit 52: current / arc sensor
52a: Rogowski coil 53: fuse
54: circuit breaker 55: SPD
56: arc detection analog circuit unit 56a: matching circuit unit
56b: signal amplifier 57a: AD conversion unit
57b: FFT 57c: unwanted band removal unit
57d: effective bandwidth power calculation unit 57e: arc bandwidth power calculation unit
57f: power comparison/warning unit 57g: effective band selection unit
60: inverter 70: distribution board
80: system monitoring unit 90: data server

Claims (4)

Matching the current and arc detected from the current/arc sensor 52 connected to the PV array 30 that generates 300-1500V direct current through the array of photovoltaic (PV) modules 31 into analog signals and An arc detection analog circuit unit 56 for amplification;
An AD conversion unit 57a converting the analog signal matched and amplified by the arc detection analog circuit unit 56 into a digital signal;
FFT (Fast Fourier Transform; 57b) for analyzing the digital signal of the AD conversion unit 57a in the frequency domain and determining the signal power distribution;
an unnecessary band removal unit 57c for removing a noise band from the signal power distribution of the FFT 57b;
an effective band power calculation unit 57d for calculating power in an effective band from the signal power distribution from which the noise band is removed by the unnecessary band removal unit 57c;
An arc band power calculator 57e for calculating arc band power when the arc is sensed by the current/arc sensor 52;
A power comparison/warning unit generating a warning signal when a difference between the active band power of the active band power calculator 57d and the arc band power of the arc band power calculator 57e is greater than a threshold value. Arc abnormality detection device for fire prevention of a photovoltaic power generation system, characterized in that it comprises (57f). According to claim 1,
An arc abnormality detection device for fire prevention of a photovoltaic power generation system, characterized in that it further comprises an effective band selection unit (57g) for monitoring the signal power distribution of the FFT (57b) and selecting an unnecessary band and an arc band. According to claim 1,
The current/arc sensor 52 is an arc abnormality detection device for fire prevention of a photovoltaic power generation system, characterized in that a Rogowski Coil; 52a. According to any one of claims 1 to 3,
The arc detection analog circuit unit 56 includes a matching circuit unit 56a that converts the current and arc detected by the current/arc sensor 52 into voltage, and the AD conversion unit by amplifying the voltage of the matching circuit unit 56a. Arc abnormality detection device for fire prevention of a photovoltaic power generation system, characterized in that it comprises a signal amplification unit (56b) transmitted to (57a).

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